JPS6226911Y2 - - Google Patents

Description

[Detailed description of the invention] This invention relates to an improvement of a fuse.

Fig. 1 shows a typical structure of a conventional fuse, in which a fuse element is placed in an insulating outer cylinder 2 whose both ends are closed with terminal metals 1, 1, and whose both ends are connected to the terminal metals 1, 1. 3 is disposed, and this fuse element 3 is embedded in an arc extinguisher 4.
Here, the length of the fuse element 3 is the length of the insulating outer cylinder 2.
The length of the fuse element 3 is usually two to three times the length of the outer cylinder 2. Therefore, the fuse element 3 is wound in a spiral as shown in FIG. located within. As for its constituent materials, porcelain or resin tube is generally used for the insulating outer cylinder 2, copper for the terminal metal 1, silver for the fuse element 3, and granular silica sand of about 10 to 200 meshes for the arc extinguisher 4. be exposed.

When an overcurrent flows through a fuse with this structure, the fuse element melts, generating an arc, and the vaporized fuse element material diffuses into the gaps between the arc-extinguishing agent particles as shown by the arrows in Figure 2. The arc extinguisher is melted and cooled by its latent heat of melting, instantly turning into an insulator, thereby cutting off overcurrent. After operation, a glassy molten product 34 with diffused fuse element material is formed as shown in FIG. This molten product becomes glass when silica sand is used as an arc quenching agent. The size of this molten product varies depending on the design of the fuse element and arc extinguisher, but for a typical fuse, the diameter is 2 to 10 mm.
It becomes a big thing. While the fuse is operating, the temperature of the molten product is several thousand degrees centigrade, but due to the low heat conductivity of the surrounding granular arc-extinguishing agent, the temperature of the insulating outer cylinder does not rise that much, and it is protected from destruction.
However, if the fuse element is in contact with or close to the insulating outer cylinder and the molten product comes into contact with it, the insulating outer cylinder will crack due to the heat shock in the case of porcelain.
Also, in the case of a resin tube, it will catch fire and burst.

Now, if we consider the case where the fuse element is wound into a spiral as shown in FIG. 1 and disposed within the outer cylinder, the position of the fuse element 3 is maintained by its own springiness. Considering the balance of forces at the center point A of the fuse element in this case, as shown in Figure 4, a constant tension F ₁ is acting in the length direction of the fuse element due to its own springiness. When even a small external force F ₂ is applied in the radial direction due to vibration, impact, etc., a large displacement occurs to balance this force. It is easy to think that the arc extinguisher protects this displacement of the fuse element, but in reality, the arc extinguisher itself moves and circulates within the outer cylinder due to vibrations, shocks, etc., and the fuse element easily moves through the arc extinguisher. It is something.

This makes it unstable to maintain the radial position of the fuse element.
There was a problem that a considerable distance was required between the fuse element and the insulating outer cylinder, and the outer cylinder had to be thick, resulting in poor storage efficiency of the fuse element.

This idea was developed by focusing on the points mentioned above, and by providing a partition made of fibrous heat-resistant insulator between the fuse element and the insulating outer cylinder, the fuse element can be displaced in the radial direction. However, by preventing the fuse element from coming into contact with the insulating outer cylinder, and by ensuring that the fibrous heat-resistant insulator performs the arc-extinguishing action in the same way as the arc-extinguishing agent when the fuse element melts, The aim is to provide a fuse that does not have these drawbacks.

An embodiment of this invention will be described below with reference to FIG. That is, in FIG. 5, reference numeral 5 denotes a partition wall made of a fibrous heat-resistant insulator, and this partition wall is provided between the fuse element 3 and the insulating outer cylinder 2. Note that the other configurations are the same as the conventional one, so explanations will be omitted. The structure of the fibrous heat-resistant insulator is cloth-like woven from long fibers or cotton-like from aggregated short fibers, and when the fuse element blows out, similar to the granular arc-extinguishing agent, it It is important that the vaporized fuse element material diffuses into its fibrous interstices, and that the material, like an arc quencher, cools the arc with its latent heat of fusion, causing the molten products to instantly It is important that it is an insulator. An example of a tube that satisfies these conditions is a glass cloth tube, and it has been confirmed that good results can be obtained by fitting this tube into the inner wall of the outer cylinder.

In a fuse with such a configuration, when an overcurrent flows and fuses the fuse element and generates an arc, the fuse element material vaporizes, and some of it diffuses into the fibrous gaps that make up the partition wall 5, causing the partition wall 5 to It is melted and cooled by its latent heat of melting together with the arc extinguishing agent 4, instantly becoming an insulator and cutting off overcurrent. After the operation, a molten product 34 is formed in which the fibrous partition wall 5 and the arc-extinguishing agent 4 are integrated, as shown in FIG. In other words, the partition wall made of a heat-resistant insulator normally maintains the position of the fuse element stably so that it does not touch or approach the outer cylinder, and when an overcurrent flows and the fuse is activated, the partition wall is made of an arc-extinguishing agent. It functions to perform a similar arc extinguishing effect. Note that if glass fiber is used as the partition wall and silica sand is used as the arc extinguisher, the molten product becomes glass.

As described above, according to this invention, since the fuse element does not come into contact with or approach the outer cylinder and damage the outer cylinder, the outer cylinder can be made smaller and the storage efficiency of the fuse element can be improved. An excellent practical effect can be obtained.

[Brief explanation of the drawing]

Fig. 1 is a longitudinal sectional view showing the structure of a conventional fuse, Fig. 2 is a transverse sectional view explaining the operating process of the fuse, Fig. 3 is a transverse sectional view showing the state of the fuse after operation, and Fig. 4 is A vector diagram illustrating the force relationship that maintains the position of the fuse element, FIG. 5 is a vertical sectional view showing an embodiment of this invention, and FIG. 6 is a horizontal sectional view showing the state of the fuse of this invention after operation. be. In the figure, 1 is a terminal metal, 2 is an insulating outer cylinder, 3 is a fuse element, 4 is an arc extinguisher, 5 is a partition made of a fibrous heat-resistant insulator, and 34 is a molten product after the fuse is operated. . Note that the same reference numerals in the figures indicate the same or corresponding parts.

Claims (1)

[Claims for Utility Model Registration] (1) An insulating outer cylinder whose both ends are closed with terminal metals, a granular arc-extinguishing agent filled in this insulating outer cylinder, and a supporting member embedded in the arc-extinguishing agent. A fuse element disposed in the insulating outer cylinder, and a fuse element disposed in the insulating outer cylinder, so that the molten product caused by the arc generated when the fuse element is blown does not reach the insulating outer cylinder. interposed between the outer cylinder and the fuse element,
A fuse that is formed of a fibrous heat-resistant insulator, and that when fused, a part of the vaporized fuse element material diffuses into the fibrous gap and has a partition wall that has the same arc-extinguishing effect as the arc-extinguishing agent. . (2) The fuse according to claim 1, wherein the partition wall made of a fibrous heat-resistant insulator is glass cloth.